Upper branch thermal Hall effect in quantum paramagnets

TL;DR

This paper proposes that the upper energy branches in quantum paramagnets can contribute to the thermal Hall effect through Berry curvature, expanding understanding of thermal transport in magnetic materials.

Contribution

It introduces a new mechanism involving upper branch dispersive bands and Berry curvature for the thermal Hall effect in quantum paramagnets, demonstrated on a kagome lattice model.

Findings

Upper branch bands can acquire Berry curvature under magnetic fields.

The mechanism is potentially universal across different lattice types.

The effect is relevant for Mott systems with large local Hilbert spaces.

Abstract

Inspired by the persistent thermal Hall effects at finite temperatures in various quantum paramagnets, we explore the origin of the thermal Hall effects from the perspective of the upper branch parts by invoking the dispersive and twisted crystal field excitations. It is shown that the upper branches of the local energy levels could hybridize and form the dispersive bands. The observation is that, upon the time-reversal symmetry breaking by the magnetic fields, these upper branch bands could acquire a Berry curvature distribution and contribute to the thermal Hall effect in the paramagnetic regime. As a proof of principle, we consider the setting on the kagom\'e lattice with one ground state singlet and an excited doublet, and show this is indeed possible. We expect this effect to be universal and has no strong connection with the underlying lattice. Although the thermal Hall signal can be contributed from other sources such as phonons and their scattering in the actual materials, we discuss the application to the Mott systems with the large local Hilbert spaces.